Divertor & Heat Routing

[ How It Works ]

How the Divertor & Heat Routing System Works

FM Integration’s fusion architecture incorporates a Divertor & Heat Routing System that manages how heat and exhaust particles are directed away from sensitive internal structures. This subsystem is essential for maintaining stable operation and protecting components such as the nano-shield, composite first wall, and rotating lattice.

The divertor provides a controlled pathway for energy and particles that naturally migrate outward from the plasma core, without revealing any proprietary engineering or physics models.

[ More Formal / Technical Tone ]

Key functions of the system can be described at a high level as follows:

1. Directing heat flow to designated surfaces:

Energetic particles that follow magnetic field lines are guided to specialized surfaces designed to absorb, spread, and manage heat safely, reducing thermal loads on the plasma-facing first wall.

2. Managing exhaust particles:

The system provides controlled routing for particles that must be removed during operation, handled safely without disclosing engineering details.

3. Supporting thermal stability:

By concentrating heat flow into defined regions, the system reduces hot spots, protects internal layers, enhances thermal distribution, and supports long-duration stability.

4. Working with magnetic shaping:

The divertor operates in cooperation with the magnetic field structure, which naturally guides outward-moving particles toward the divertor region. No proprietary magnetic shaping or control methods are disclosed.

[ How It Works ]

Why It Matters

The Divertor & Heat Routing System improves reactor performance by:

  • Protecting sensitive internal layers
  • Controlling where heat is absorbed
  • Routing exhaust particles safely
  • Improving long-term stability
  • Enabling consistent operation under demanding conditions
[ How It Works ]

What We Don’t Disclose:

To protect intellectual property, FMI does not reveal:

  • Divertor plate materials
  • Cooling structures or geometries
  • Thermal transfer mechanisms
  • Integration details with magnetic shaping
  • Engineering methods or modeling
  • Any advanced routing techniques specific to the design
[ Climate Solutions ]

Our Summary:

The Divertor & Heat Routing System acts as a controlled outlet for heat and exhaust, guiding energy into designated components and protecting the reactor’s internal architecture. All proprietary designs, materials, and engineering details remain strictly confidential.